INDOOR POOL
INDOOR POOL
CONTENTS DE-HUMIDIFICATION IN INDOOR SWIMMING POOLS 2 DESIGN PROPERTIES OF THE INDOOR POOL DE-HUMIDIFYING UNIT 4 FRAME STRUCTURE 6 PANEL STRUCTURE 6 DRAINAGE SYSTEM 7 OUR DISTINCTIONS 8 - The Use and Advantages of Composite Material 8 - Psychometric Calculation Software 9 - Magnelis Sheet Metal 10 TECHNICAL PROPERTIES OF THE INDOOR POOL DE-HUMIDIFYING UNIT 12 OPERATING PRINCIPLE 14 DIMENSIONS 16 OPERATING SCENARIOS 18 - Scenario 1: Daytime Operation - Heavy Pool Activity 18 - Scenario 2: Light Pool Activity 18 - Scenario 3: Seasonal Transition Operation (Free Cooling) - No De-humidification Process 19 - Scenario 4: Night Time Operation - No De-humidification Process 19 THE AUTOMATION SYSTEM 20
De-humidification in Indoor Swimming Pools Table of Condensation Amounts [kg/h m 2 ] Humidity in indoor pool spaces is an element that disrupts the conditions of comfort and is detrimental to the concrete, steel, and wood sections of the building when unless it is controlled. During winter months and summer evenings when the outdoortemperature is lower than indoor temperature, the water vapor in the air causes visible condensation on wall surfaces, and particularly on window glasses. In cases where relative humidity remains over 60% for extended periods, it will inevitably have detrimental effects on the building elements. When chlorine gas that evaporates from the pool water reacts with the condensed water it produces hydrochloric acid which is an abrasive chemical, accelerating corrosion. High humidity also facilitates the growth of bacteria and fungi that are harmful to human health. Maintaining humidity between 50 and 60% will significantly reduce the numbers and activity of microorganisms. In summary, humidity is a component of air that needs to be controlled in pool spaces. Air Temperature ( C) RELATIVE HUMIDITY (%) 50 55 60 50 55 60 50 55 60 50 55 60 50 55 60 50 55 60 20 0,273 0,256 0,235 0,328 0,310 0,289 0,382 0,365 0,344 0,436 0,419 0,398 0,525 0,508 0,487 0,615 0,598 0,577 21 0,264 0,241 0,220 0,318 0,296 0,275 0,373 0,350 0,329 0,427 0,404 0,383 0,516 0,493 0,473 0,605 0,583 0,562 22 0,249 0,227 0,205 0,304 0,281 0,260 0,358 0,335 0,314 0,412 0,389 0,368 0,502 0,479 0,458 0,591 0,568 0,547 23 0,235 0,212 0,191 0,289 0,266 0,245 0,344 0,320 0,299 0,398 0,375 0,354 0,487 0,464 0,443 0,576 0,553 0,532 24 0,220 0,197 0,176 0,275 0,252 0,230 0,329 0,306 0,284 0,383 0,360 0,339 0,473 0,449 0,428 0,562 0,539 0,517 25 0,206 0,183 0,161 0,260 0,237 0,215 0,315 0,291 0,270 0,369 0,345 0,324 0,458 0,435 0,413 0,547 0,524 0,503 26 0,191 0,168 0,146 0,246 0,222 0,200 0,300 0,276 0,255 0,354 0,331 0,309 0,444 0,420 0,398 0,533 0,509 0,488 27 0,177 0,153 0,131 0,231 0,208 0,186 0,286 0,262 0,240 0,340 0,316 0,294 0,429 0,405 0,384 0,518 0,495 0,473 28 0,162 0,139 0,117 0,217 0,193 0,171 0,271 0,247 0,225 0,325 0,301 0,279 0,415 0,391 0,369 0,504 0,480 0,458 29 0,148 0,124 0,097 0,202 0,178 0,151 0,257 0,233 0,205 0,311 0,287 0,260 0,400 0,376 0,349 0,490 0,465 0,438 30 0,134 0,109 0,071 0,188 0,164 0,126 0,242 0,218 0,180 0,296 0,272 0,234 0,386 0,361 0,324 0,475 0,451 0,413 Water Temp. 24 26 28 30 32 34 ( C) The figures in the table above were calculated for a pool surface area of 1 m 2, and assuming a Pool Activity Factor of 1. Follow Example 1 for different surface areas and Pool Activity Factors. Design Conditions of Swimming Pools Pool Type Air Temp. C Water Temp. C Rela ve Humidity,% Recrea onal Pools 24-29 24-29 50-60 Therapy Pools 27 29 29 35 50 60 Compe on Pools 26 29 24 28 50 60 Diving Pools 27 29 27 32 50 60 Rehabilita on Pools 29 32 29 32 50 60 Hotel Pools 28 29 28 30 50 60 Thermal Baths 27 29 36 40 50 60 Reference: Ashrae HVAC Applications 2015 Handbook, Section 5. 2
Pool Type Ac vity Factor (F a ) When Pool Cover is in Use 0,02 Pools Outside Service Hours 0,5 Residen al Pools 0,5 Floor Pools 0,65 Therapy Pools 0,65 Hotel Pools 0,8 Public Pools 1 Thermal Baths 1 Wave Pools 1,5 W p = 4 x 10-5 x A x (p w - p a ) x F a W p : The amount of evaporation, kg/hour A : Pool surface area, m 2 P w : Vapour saturation pressure at surface temperature of pool, kp a P a F a : Saturation pressure at dew point temperature of the space, kp a : Activity factor The Evaporation Amount Table above that was prepared using this equation is used for making practical and quick calculations. EXAMPLE 1: Let us calculate the amount of evaporation that will occur in a 55 m 2 hotel pool with a pool surface temperature of 28 C, in an ambient temperature of 27 C and relative humidity of 55%. SOLUTION: The evaporation coefficient which corresponds to the ambient conditions and water temperature provided is read from the Evaporation Amount Table. The non-activity dependent evaporation on the surface of 1 m 2 of pool surface with a pool surface temperature of 28 C, in an ambient temperature of 27 C and relative humidity of 55% is read from the table as 0.262 kg/h m 2. The Pa value according to the type of pool is determined from the activity Factor table. 0.8 (For Hotel Pools) Evaporation Amount is calculated as: 0.262 x 55 x 0.8 = 11.53 kg/h. 3
Tips for Energy Conservation in Indoor Pools Energy Losses in Indoor Pools De-humidification in Indoor Pools Other 3% Ventilation 27% Vaporisation 70% Ventilation is of critical importance for creating suitable indoor air quality, user comfort, and humidity control in indoor pool spaces. According to Ashrae Standard Nr. 62-1 on Ventilation for Acceptable Indoor Air Quality, a minimum of 2.4 L/s.m 2 must be provided for the total surface area of the pool and deck, and a minim um of 4 l/s fresh air per person must be provided if there is a spectator stand. The standard also states that more fresh air can also be used for the control of humidity. Ashrae s System and Applications Handbook recommends 4-6 changes of air for rehabilitation pools and pools without spectators, and 6-8 changes of air for pools with spectators. Ventilation system design is of critical importance in terms of energy efficiency. Constant de-humidification is required in indoor poor areas due to Evaporation. While the pool is in use, the minimum amount of fresh air required by the principles must be adjusted, and the fresh air should be increased depending on the number of spectators; fresh air can also be disabled when the pool is not in use. 4
The ASHRAE HVAC Handbook recommends that relative humidity levels of indoor environments be maintained between 40-60%. If relative humidity level is maintained below 50% evaporation from the pool and from people will increase, and if it exceeds 60%, it causes moulding and deformations in the building structure while also exceeding conditions of comfort for people. Furthermore creating a slightly negative pressure in the pool area will prevent the transfer of warm and humid air to other sections of the building and prevents the pool smell from seeping into adjacent spaces. Maintaining a proper balance between air and water temperatures will influence the comfort of users as well as energy efficiency. It is recommended that the air temperature be maintained two degrees higher than the temperature of the pool water. Cases where air temperature is higher than water temperature only apply to pools for the elderly, health pools, and hydro-massage pools. Air temperature may need to be maintained between 25 C to 27 C for reasons of comfort for users. High water temperature and low air temperature greatly increase the rate of evaporation, and this issue must be taken into consideration while designing the dehumidification system. The use of pool covers stops evaporation to a large extent, thus evaporation can be decreased outside the hours of operation in such cases of high air and low pool water temperature. The use of cover s in indoo r pool s minimi se s evap or atio n. When evaporation decreases, the indoor environment s need for ventilation and de-humidification is minimised. The practice of covering pool surfaces when the pool is not in use also reduces heat losses, reducing operational costs in a most effective manner. A saving of 50-70% can be achieved during periods when pool covers are used. Since there are many types of de -humidification requirements for climate control for indoor pools, a selection needs to be made between several de-humidification strategies with completely different initial investment and operational cost structures. Rather than systems which do not utilize condenser heat, systems which use this to reheat the air, and recover energy by heating pool water should be selected. The design of collective use pool buildings can be complicated and require consideration of many issues, such as suitable air current to prevent problems of condensation on building walls, air distribution at suitable velocity, and minimum air flow at the surface of the pool to maintain low evaporation. Ambient Temperature Pool Cover De-humidification 5
DESIGN PROPERTIES OF THE INDOOR POOL DE-HUMIDIFYING UNIT
Frame Structure The frame structure of the Indoor Pool De-Humidifying Unit comprises electrostatic oven painted box profiles manufactured from steel material with dimensions of 30x30 and 30x60 mm and a thickness of 2 mm, and aluminum corner and plastic fittings. The Indoor Pool De-Humidifying Unit is class D1, the highest class according to the EN 1886 Mechanical Strength test. TB1 Frame Structure without Thermal Bridging High efficient plate heat exchanger Epoxy Coated Condenser Surface Automation Panel Plug Fan G4 Panel Fresh Air Filter Scroll Compressor (R410A) G4 Panel Exhaust Air Filter Magnelis Coated, Electrostatic Powder Painted Interior Surface Evaporator Epoxy Coated Condenser Surface Water Heater, Epoxy Surface Coating 8
Panel structure which forms the casing of the Indoor Pool De-Humidifying Unit is the most and effective equipment that affects the overall mechanical performance of the unit. The panel structure of the Indoor Pool De-Humidifying Unit is designed to prevent thermal bridging between the internal and external environment. Contact between inner and outer surface sheet metals that are mounted on the panel structure made up of PVC-based panel profiles is completely prevented, thus providing a thermal bridge free structure. This property has significant part in achieving a thermal bridge free class of TB1 for the entire frame in tests conducted in accordance to the EN 1886 standard. The air leakage class has been measured as L1 due to EPDM hermetic seals used on connecting surfaces between the panel and the frame profile. Panel Structure Typically, 50 mm rock wool in 70 kg/m 3 density is used as panel insulation material. With its PVC frame structure and standard insulation, its Thermal Transmittance Class is T2 according to EN 1886. Connecting screws that are used to connect panels to the frame structure are hidden on the outer sheet metal, and provides a smooth, aesthetic view on the outside. Screw caps on the screw heads prevent contact with the external environment to avoid corrosion and thermal bridging. Custom manufactured EPDM-based porous seals with low thermal transmittance factor are used on the joints of panels and profiles. EN 1886:2007 Characteristics Mechanical Strength D3 D2 D1 Casing Air Leakage L3 L2 L1 Filter By-Pass Leakage G1-F5 F6 F7 F8 F9 Thermal Transmittance T5 T4 T3 T2 T1 Thermal Bridge TB5 TB4 TB3 TB2 TB1 Ratings 9
The Drainage System If surface temperature values in cooling coils are lower than the dew point of air, the water vapor contained within the air passing over the exchanger will condense into the liquid phase. This condensed water must be collected from the exchanger surface and removed from the unit as soon as possible. Otherwise, wet spaces will form within the unit and cause growth of microorganisms. Drain pans are manufactured from stainless steel sheet as a standard. The pan s double inclined design allows the water to accumulate in the corner. The water is then drained with a drainage pipe and collective trap system. The rounded design of the edge connecting to the drainage pipe allows water to be drained 100% from the pan, keeping the pan dry at all times. Insulation and exterior steel covering has been applied under condensation pans preventing thermal bridging as well as any condensation that may occur beneath the pan. Drop eliminators manufactured of Polypropylene material are used to prevent water droplets that condense on the exchanger surface from drifting with air to other sections. Negative Pressure P H 1 = + 20 mm 10 H s (mm) = P x 0,075 mm Another important piece of equipment in the drainage system is the trap. The purpose of this system is to eliminate the effects of the pressure difference between internal pressure of the air handling unit and the drainage line, facilitating the drainage of water. It is also to prevent odours that may form in the sewage installation from reaching the air handling unit interior. For this reason, the calculation and selection of the drainage system is very important. An error in application will cause flooding within the air handling unit. Hygiene Properties and Corrosion Resistance The Indoor Pool De-Humidifying Unit is manufactured with high corrosion resistance. This is achieved with the practices mentioned below. All interior metal surfaces are electrostatic oven painted. The evaporator surface is manufactured to conform to hydrophilic, while other exchanger surfaces are manufactured to conform to epoxy coated hygiene standards. All plastic materials used do not permit the growth of bacteria and funguses due to special additives. The entire interior surface has a smooth design and is thus easy to clean. 10
Evaporation calculations can be performed with great accuracy for all types of pools, with the Indoor Pool evaporation estimator. The software calculates evaporation amounts based on various use conditions, water temperature, air temperature, and pool surface area, according to the ASHRAE calculation method. Psychometric Calculation Software 11
TECHNICAL PROPERTIES OF THE INDOOR POOL DE-HUMIDIFYING UNIT
Operating Principle The Indoor Pool De-Humidifying Unit is different from conventional system Indoor Pool De-Humidifying Units due to its low overall power consumption. In conventional system poolside dehumidifying air handling units, while supplying the fresh air needed, the moisture from the humid air received from the pool environment is exhausted in equal ratio to the fresh air. This leads to unnecessary energy losses and in consequence, an increase in the electrical energy consumed by the compressor. Since exhaust is performed before the cooling process, does not waste energy, and provides the desired de-humidifying capacity with a smaller compressor capacity. Thus over 8% of electricity is saved as compared to conventional units. In addition to the heat energy absorbed by the cooler while cooling is performed for dehumidification purposes, the work applied by the compressor is also transferred in the form of heat energy to the supply air via the condenser. This causes uncontrolled blast temperatures (45-50 C) and disrupts the comfort conditions of the pool space other than in winter conditions. Electrical Power Consumed kw De-humidification Capacity kg/h BHS Conventional Systems 14
A specially designed optional air cooled dual condenser system is used in the Indoor Pool De-Humidifying Unit. One of these condensers is placed on the fresh air line while the other is placed on the exhaust line. While the needed fresh air is being supplied, the exhausted return air is passed over the exhaust condenser without being subjected to cooling, and discharged into the outside environment. Thus the heat energy generated by the compressor for the cooling process is discharged over the exhaust condenser, and not added to the supply air temperature. With this method, supply air temperature can be controlled and maintained in the range +33 C / +35 C which does not disrupt the conditions of comfort. 1- Compressor 2- Evaporator 3- Plate Type Heat Recovery 4- Fresh Air Condenser 5- Exhaust Condenser 6- Water Heating Coil FA : Fresh Air SA : Supply Air RA : Return Air EA : Exhaust Air 15
Dimensions 16
Psychometric Table NORMAL TEMPERATURE Units SI SEA LEVEL Barometric Pressure: 101.325 kpa Pool Space Condition Exit Point for Heat Recovery Exit Point for DX Exit Point for Mixture Air Exit Point for Heat Recovery Exit Point for Condenser - Supply Temperature 1. In Pool Surface Area calculations according to the Ashrae HVAC Applications 2015 Handbook, Pool Water Surface Temperature was taken as 27 C, the Ambient Temperature as 30 C, Relative Humidity as 55%, and Activity Factor as 1.5. 2. In Pool Surface Area calculations according to the Ashrae HVAC Applications 2015 Handbook, Pool Water Surface Temperature was taken as 27 C, the Ambient Temperature as 30 C, Relative Humidity as 55%, and Activity Factor as 0.5. 17
Scenario 1 Daytime Operation - Heavy Pool Activity Operating Scenarios Air Flow Rate Cooling System Condenser Fans Operates with 30% (maximum) Fresh Air and 70% Return Air The Cooling System is Enabled (De-humidifica on is Performed) Both or One of the Condensers will be Enabled The Return Fan and Supply Fan are Enabled Scenario 2 Light Pool Activity Air Flow Rate Cooling System Condenser Fans Hot Water Hea ng Coil Operates with 100% Return Air, Fresh Air is not Needed The Cooling System is Enabled (De-humidifica on is Performed) The Supply Line Condenser is Emabled, the Exhaust Condenser is Disabled The Return Fan and Supply Fan are Enabled Will Come Online as Needed 18
Scenario 3 Seasonal Transition Operation - No De-humidification Process Air Flow Rate Cooling System Condenser Fans Hot Water Hea ng Coil Operates with 100% Fresh Air The Cooling System is Disabled (De-humidifica on is not Performed) The Supply Line Condenser is Disabled, the Exhaust Condenser is Disabled The Return Fan and Supply Fan are Enabled Will Come Online as Needed Scenario 4 Night Time Operation - No De-humidification Process Air Flow Rate Cooling System Condenser Fans Hot Water Hea ng Coil Operates with 100% Return Air The Cooling System is Disabled (De-humidifaciton is not Performed) The Supply Line Condenser is Disabled, the Exhaust Condenser is Disabled The Return Fan is Disabled, the Supply Fan is Enabled Will Come Online as Needed 19
The Automation System The automation system of the Indoor Pool De- Humidifying Unit includes all control and power components needed to implement operating scenarios on the unit and within the MCC-DCC panel. All scenarios are pre-loaded in the control card. Power supply from the mains is sufficient for commissioning, no additional automation application is needed. Fresh Air Humidity and Temperature Sensor Pressure Differential Switch MCC-DDC Panel Pressure Differential Switch Low-High Pressurestat Supply Air Humidity and Temperature Sensor Return Air Humidity and Temperature Sensor Control Point Applica on Point Equipment Used Humidity and Temperature Control Outdoor Air Temperature, Return Air Temperature, Supply Air Temperature Humidity and Temperature Sensor Filter Dir ness Control Fresh Air Filter and Return Air Filter Pressure Differen al Switch (0-250Pa) High-Low Pressure Control Li and Force Line of the Compressor Low-High Pressurestat with Manuel Reset Damper Control Fresh Air, Mixture, Bypass, Intake Line Dampers Propor onal and On/Off Damper Motor 20
INDOOR POOL
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